A method and a circuit system for driving a nebulizer are provided. When the nebulizer receives acoustic waves, a control circuit extracts audio signals from the acoustic waves. Afterwards, the control circuit determines if the audio signals are within a predetermined frequency range, and can determine whether or not to drive a circuit to produce an aerosol based on the audio signals. Further, a volume of the acoustic waves can also be used to determine whether or not to produce the aerosol, and also determine an output rate of the aerosol. The circuit system of the nebulizer includes an audio receiver for receiving the acoustic waves, an aerosol generator for producing the aerosol, and the control circuit used to control a driving circuit of the aerosol generator to drive a vibrational element to produce the aerosol through vibration in response to the audio signals and the volume.

An apparatus and method for providing a nebula or aerosol to a patient is described. In one aspect, the nebulizer is composed of a minimum number of parts to reduce complexity for automated or human assembly. The nebulizer may include an inhalation valve, exhalation valve and biasing member integrated into a single diaphragm structure that may be connected with an actuator and inserted into a housing for controlling nebulization of a medicine to a patient in response to the patient's breathing or in a continuous nebulization mode.

An inhaler, preferably for insertion into a nostril, in particular a horse's nostril, with an inhalation valve, which has a movable valve element, whereby the valve element is designed in an annular manner and has an outer edge and an inner edge, whereby the valve element is fastened at the outer edge, the inner edge forms the boundary of an indentation of the valve element, and the inhalation valve has a valve body seat that corresponds to the inner edge.

A nasal mask has a flexible bottom edge portion and side portions. A delivery device includes a holding chamber coupled to the nasal mask. A method of delivering an inhalable substance includes positioning a nose of a user in a cavity of the nasal mask, inhaling through the nose, and orally soothing the user with a soothing device.

A personalized drug delivery apparatus including drug containing structure; a spout configured to receive full lung exhalation; a mechanism configured to determine a personalized drug dosage according to the exhalation, the spout further configured to enable inhalation of the determined dosage.

A multichannel vaporizer including multiple vapor sources and a user interface to modify a proportion of vapors from the vapor sources into a customized vapor to be delivered to the mouthpiece. Also, a method of providing a customized combination of vapors including adjusting a user interface to control an adjustable vapor manifold with a plurality of vapor paths defined between the plurality of vapor sources and a mouthpiece for issuing vapors.

A medical device includes a user interface component and an energy harvesting system coupled to the user interface component. The energy harvesting system energy includes a harvesting component, a power storage device connected to the energy harvesting component and an output is coupled to the user interface and operably connected to the power storage device. A method of using the medical device is also provided.

An elastomeric component includes a body feature and a retaining feature coupled to the body feature. The retaining feature includes an insertion end portion, and a retention end portion spaced apart from the insertion end portion along a longitudinal axis. The insertion end portion defines a catch spaced apart from the retention end portion and having a contact location adapted to make first contact with an edge of a retaining hole. The contact location is spaced apart from the catch a first distance. The retaining feature has a blind pocket extending from the retention end portion interiorly of the retaining feature along the longitudinal axis. The blind pocket terminates at an end location spaced from the catch. The elastomeric component may be coupled to a wall defining the retaining hole. Methods of assembly, and an apparatus for installation, are also provided.

A positive exhalation pressure device (1) is described. The device (1) comprises a housing (2) having an annular chamber (5), a chamber inlet (6) configured to permit air into the chamber, a chamber outlet (7) configured to permit air out of the chamber, and a mouthpiece (8) in fluid communication with the chamber inlet. A movable body such as a ball (3) is disposed in the housing within the annular chamber and configured to revolve around the annular chamber in response to flow of air through the chamber from the chamber inlet to the chamber outlet. The movable body is configured to at least partially block the chamber outlet as it revolves around the annular chamber causing cyclical fluctuations in airflow resistance.

The present invention provides a new inhaler device for the storage and/or administration of inhalable liquids to a patient offering one or more advantages or improvements over known inhalers, particularly inhalers for the delivery of halogenated volatile liquids such as methoxyflurane for use as an analgesic.